Week 2- Skeletal System.pdf

Full Transcript

Week 2

Human Anatomy & Physiology - 1 (HMG380)

SKELETAL SYSTEM

Dr. Merin Thomas
[email protected]
Office hours : Monday& Wednesday, 3.00pm to 5.00pm
Tuesday & Thursday, 1.00pm to 3.00pm
 Learning Objectives

Functions of Bone & Skeletal system
Divisions of Skeletal System
Types of Bones
Bones that make up the skull, Vertebral Column, Thoracic Cage, Pelvis
Histology of Bone Tissue
Fracture and Repair of Bone
Bone’s role in Calcium Homeostasis
Joints
 Levels of Structural Organization - LEVEL 3 - TISSUE LEVEL

Epithelial Tissue Connective Tissue Muscular Tissue Nervous Tissue
Covers body surfaces, Connects, supports, and protects Contracts to make body
lines hollow organs & body organs while distributing parts move & in the Carries information
cavities, and forms blood vessels to other tissues process generates heat from one part of the
glands. Loose Connective body to another
Smooth Muscle through nerve
Based on shape of Tissue
impulses
the cell 2 types of cells

Dense Connective
Tissue Skeletal Muscle

Based on number Cardiac Muscle

of layers of cells Special Connective
Tissue
Three parts:
CNS, PNS, ANS
 The types connective tissue that belong to the skeletal system are
Specialized connective tissue: bone ,cartilage
Dense regular connective tissue: tendons & ligaments
They differ from one another based on the composition of the
extra cellular matrix.

Extracellular matrix is mainly made up of collagen fibers,
ground substance, organic molecules, water and minerals

The type and quantity of each varies with different type of
tissue
 Differences between bone & cartilage

BONE CARTILAGE
Long, short, flat, irregular, sesamoid Hyaline cartilage, elastic
TYPES cartilage, fibrocartilage

Protection Reduces friction at joints
Assist in movement Acts as shock absorbers b/w
Framework of body weight bearing bones
FUNCTION Stores minerals Maintains shapes AND
Produces blood cells flexibility of certain appendages

Vascularised Avascular
Made up of specialized cells - Made up of specialized cells -
STRUCTURE osteoblasts, osteocytes, osteoclasts chondroblasts & chondrocytes

Makes up majority of the axial and Found between bones
appendicular skeleton Along respiratory tract
LOCATION And few other places where
flexibility is needed
 Bone tissue is a complex and dynamic living tissue
Bone tissue is continuously growing, remodeling, and repairing itself.
It contributes to homeostasis of the body by providing support and
protection, producing blood cells, and storing minerals and triglycerides.

The entire framework of bones and their cartilages constitute the skeletal
system.

The study of bone structure and the treatment of bone disorders is referred
to as osteology

The process of bone formation is called as ossification
 The adult human skeleton consists of 206 named bones, most of which
are paired

The skeletons of infants and children have more than 206 bones
because some of their bones fuse later in life.
 Functions of Bone Tissue

1. Supports soft tissue and provides attachment for skeletal muscles.

2. Protects internal organs.

3. Assists in movement, along with skeletal muscles.

4. Stores and releases minerals.

5. Contains red bone marrow, which produces blood cells , and yellow
bone marrow, which stores triglycerides (fats).
 Divisions of Skeletal System

Bones of the adult skeleton are grouped into two

Axial skeleton

Appendicular skeleton
 Divisions of Skeletal System

Adapted from Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 203
 TYPES OF BONES

Almost all bones of the body can be classified into five main types based
on shape

1. Long Bones

2. Short Bones

3. Flat Bones
4. Irregular Bones
5. Sesamoid Bones
 TYPES OF BONES

Greater length than width Afford
considerable
Slightly curved for protection and
strength provide extensive
Vary tremendously in areas for muscle
size attachment

Complex
shapes &
Cube-shaped and cannot be
are nearly equal grouped
in length and into any of
width. the previous
categories.

Develop in certain tendons where there is
considerable friction, tension, and physical strain
Adapted from Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 205
 PARTS OF A LONG BONE

PROXIMAL EPIPHYSIS

Epiphysis - Proximal & Distal ends of the bone METAPHYSIS

Diaphysis - long, cylindrical, main portion of the
bone

Metaphysis - the regions between the diaphysis and
the epiphyses DIAPHYSIS

Articular cartilage - thin layer of hyaline cartilage
covering the part of the epiphysis where the bone
forms a joint) with another bone.

reduces friction and absorbs shock at freely METAPHYSIS

movable joints
DISTAL EPIPHYSIS

From Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 179
 PARTS OF A BONE
Articular Cartilage

Periosteum - tough connective tissue sheath and its associated
blood supply that surrounds the bone surface wherever it is not covered
by articular cartilage

also protects the bone, assists in fracture repair, helps nourish
bone tissue, and serves as an attachment point for ligaments and
tendons.

The medullary cavity or marrow cavity, is a hollow, cylindrical
space within the diaphysis that contains fatty yellow bone marrow and
numerous blood vessels.

The endosteum is a thin membrane that lines the medullary cavity
and the internal spaces of spongy bone.

It contains a single layer of osteoprogenitor cells and a small
amount of connective tissue.
 SKULL/CRANIUM

The skull is the bony framework of the head.
Contains 22 bones (not including the bones of the middle ears)
Rests on the superior end of the vertebral column
The bones of the skull are grouped into two parts:
1. Cranial cavity formed by 8 bones held together by joints called as sutures;
Encloses & protects the brain

2. Facial bones forms the anterior part of the skull and is made up of 14 bones
SKULL/CRANIUM
PTERION
SKULL/CRANIUM
 FEATURES OF THE SKULL/CRANIUM

Fontanelles are mesenchyme-filled spaces between cranial cavity bones that are
present at birth.
 FEATURES & FUNCTIONS OF THE SKULL/CRANIUM

Other openings or spaces are also seen in the skull
Nasal Cavity, Orbits, Paranasal air sinuses etc.
Space within temporal bone – 3 ossicles of middle ear
Mandible - only moveable bone of the skull
Surface markings - foramina, fissures, processes etc.
Protects & stabilizes the positions of the brain, blood vessels, lymphatic
vessels, and nerves
The outer surfaces of the bones provide areas of attachment for muscles that
move various parts of the head & for some muscles that produce facial
expressions
Together, the cranial cavity and facial bones protect and support the delicate
special sense organs for vision, taste, smell, hearing, and equilibrium
 VERTEBRAL COLUMN

Composed of a series of bones called vertebrae
(singular is vertebra), enclosing & protecting the
spinal cord.
The vertebral column, the sternum, and the ribs
form the skeleton of the trunk of the body
Approx. 71 cm in an avg. adult male & about 61
cm in an avg. adult female
It is a strong, flexible rod
It supports the head and serves as a point of
attachment for the ribs, pelvic girdle, and muscles of
the back and upper limbs.
 VERTEBRAL COLUMN - VERTEBRAE

7 cervical vertebrae in the neck region.
12 thoracic vertebrae posterior to the thoracic cavity.
5 lumbar vertebrae supporting the lower back.
5 sacral vertebrae - which fuse by adulthood to form 1
sacrum.
4 coccygeal vertebrae - which fuse by adulthood to
form 1 coccyx
VERTEBRAL COLUMN - CURVATURES

SECONDARY CURVATURE

PRIMARY CURVATURE

SECONDARY CURVATURE

PRIMARY CURVATURE

From Principles of
Anatomy and
Physiology, by Tortora,
Gerard J. And Bryan H
Derrickson, Wiley &
Sons, 2020,p 224
 VERTEBRAL COLUMN - ABNORMAL CURVATURES

Lateral bending of the Increase in the An increase in the
vertebral column, thoracic curve of the lumbar curve of the
usually in the thoracic vertebral column that vertebral column
region. produces a
“hunchback” look

Adapted from Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 238
 THORACIC CAGE

Bony enclosure formed by the
Sternum,
Ribs and their costal cartilages, and
Bodies of the thoracic vertebrae.
The thoracic cage is narrower at its
superior end and broader at its inferior
end and is flattened from front to back.

Encloses and protects the organs in the
thoracic and superior abdominal cavities,
provides support for the bones of the
upper limbs
 THORACIC CAGE - BONES FORMING

RIBS
12 pairs
STERNUM
Attached to sternum anteriorly and thoracic
FLAT BONE vertebrae posteriorly
From Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 234 -235
 THORACIC CAGE - BONES FORMING

Thoracic Vertebrae

Adapted from Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 236
 PELVIS

The pelvic (hip) girdle consists of the two hip bones
The hip bones unite anteriorly at a joint called
the pubic symphysis.

They unite posteriorly with the sacrum at the
sacroiliac joints.

The complete ring composed of the
Hip bones (Pubic symphysis & Sacroiliac joints)
Sacrum, and
Coccyx
forms a deep, basin like structure called the bony
pelvis From Principles of Anatomy and Physiology, by Tortora, Gerard J.
And Bryan H Derrickson, Wiley & Sons, 2020,p 251
 PELVIS

Functionally, the bony pelvis provides a
strong and stable support for the
vertebral column and pelvic and lower
abdominal organs.

The pelvic girdle of the bony pelvis also
connects the bones of the lower limbs to
the axial skeleton.

There are structural differences
between male and female pelvis

From Principles of Anatomy and Physiology, by Tortora, Gerard
J. And Bryan H Derrickson, Wiley & Sons, 2020,p 251
 PELVIS

From Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 253 -255
 PELVIS - GENDER DIFFERENCE

Female Pelvis Male Pelvis

From Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 256
 HISTOLOGY OF BONE

By weight, bone is composed of 60% inorganic component, 30% organic
component and 10% water.

Approximately 30% of this organic matrix is collagen; the remainder
includes various non collagenous proteins, glycoproteins and
carbohydrates.

The proportions of these components vary with age, location and
metabolic status.
 HISTOLOGY OF BONE

Majority of the inorganic mineral salts are in the form of
microcrystalline hydroxyapatite (Ca10 (PO4)6 (OH)2).

The microcrystals confer hardness and much of the rigidity of bone and
are the main reason why bone is easily seen on radiographs.

The major ions in bone mineral include calcium and phosphate among
others

Less numerous ions are citrate, magnesium, sodium, potassium, fluoride,
chloride, iron, zinc, copper, aluminum, lead, strontium, silicon and boron,
many of which are present only in trace quantities.
 HISTOLOGY OF BONE

The process of bone tissue formation is called ossification
The deposition of calcium salts (Calcium carbonate or some other
insoluble calcium compound) is called as Calcification.

Ossification and calcification are NOT the same.
Calcification occurs normally during the formation of bone.
However, calcium can also be deposited abnormally in soft tissue.
This causes soft tissue to become hard – could be pathological.
 HISTOLOGY OF BONE

A bone’s hardness depends on the crystallized inorganic mineral
salts, a bone’s flexibility depends on its collagen fibers.
 HISTOLOGY OF BONE

BONE tissue contains 4 types of cells
1. Osteoprogenitor cells
2. Osteoblasts
3. Osteocytes
4. Osteoclasts

From Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 181
 HISTOLOGY OF BONE

Unspecialized bone stem cells derived from mesenchyme, the tissue from
which almost all connective tissues are formed.
The only bone cells to undergo cell division; the resulting cells develop into
osteoblasts.
Found along the inner osteogenic layer of the periosteum, in the endosteum,
OSTEOPROGENITOR CELLS

and in the canals within bone that contain blood vessels.
Bone-building cells
Synthesize & secrete collagen fibers and other organic components needed to
build the extracellular matrix of bone tissue, a process called bone deposition

OSTEOBLASTS
Initiates calcification
As osteoblasts surround themselves with extra-cellular matrix, they become
trapped in their secretions and become osteocytes.

Mature bone cells
Main cells in bone tissue and maintain its daily metabolism, such as the
exchange of nutrients and wastes with the blood.
OSTEOCYTES
 HISTOLOGY OF BONE
Huge cells derived from the fusion of as many as 50 monocytes (a type
of white blood cell) and are concentrated in the endosteum.

On the side of the cell that faces the bone surface, the osteoclast’s plasma
membrane is deeply folded into a ruffled border.

Here the cell releases powerful lysosomal enzymes and acids that
digest the protein and mineral components of the underlying
extracellular bone matrix.

OSTEOCLASTS This breakdown of bone extracellular matrix, termed bone
resorption is part of the normal development, maintenance, and
repair of bone.

In response to certain hormones, osteoclasts help regulate blood
calcium level

They are also target cells for drug therapy used to treat osteoporosis
 HISTOLOGY OF BONE

Bone is not completely solid but has many small spaces between its cells and
extracellular matrix components.
Some spaces serve as channels for blood vessels that supply bone cells with
nutrients.
Other spaces act as storage areas for red bone marrow. Depending on the size
and distribution of the spaces, the regions of a bone may be categorized as
compact or spongy
Overall, about 80% of the skeleton is compact bone and 20% is spongy bone.
 FRACTURE AND REPAIR OF BONE

From Principles of Anatomy and Physiology, by Tortora, Gerard J. And Bryan H Derrickson, Wiley & Sons, 2020,p 193
BONE’S ROLE IN CALCIUM HOMEOSTASIS
BONE’S ROLE IN CALCIUM HOMEOSTASIS

From Principles of Anatomy and Physiology, by
Tortora, Gerard J. And Bryan H Derrickson,
Wiley & Sons, 2020,p 196
 JOINTS

A joint, also called an articulation or arthrosis, is a point of contact between
two bones, between bone and cartilage, or between bone and teeth.
Long bones articulate by their ends, flat bones by margins & in irregular
bones their surfaces are articular
The scientific study of joints is termed arthrology. The study of motion of the
human body is called kinesiology.
Joints are classified into three principal types based upon the structure of the
joint:
1. Fibrous Joints
2. Cartilaginous Joints
3. Synovial Joints
Intervertebral Joints - B/w articular surfaces of adjacent 1st Carpometacarpal Joint - B/w articular surfaces of trapezium &
vertebrae- slight movement 1st Metacarpal bone- movement around two axes

Elbow Joint- B/w articular surfaces of Humerus and Ulna
and radius- movement around one axis Proximal Radioulnar Joint- B/w articular surfaces of proximal end
of Radius & Ulna- Rotation

Shoulder Joint- B/w articular surfaces of Scapula & Atlantoccipital Joint- B/w articular surfaces of Atlas & Occipital
Humerus- Movement around multiple axes bone- Movement around two axes
 SYNOVIAL JOINTS - INSIDE JOINT CAVITY

ARTICULAR SURFACES are
covered
with articular cartilage

Joint cavity enveloped
completely by an articular
capsule

Joint presents a CAVITY which is filled with
viscous synovial fluid
JOINTS - TYPES OF MOVEMENTS
 OSTEOPOROSIS

Bone resorption (breakdown) outpaces bone deposition (formation)
In large part this is due to depletion of calcium from the body— more calcium is
lost in urine, feces, and sweat than is absorbed from the diet.
Older women suffer from osteoporosis more often than men for two reasons:
(1) Women’s bones are less massive than men’s bones, and
(2) Production of estrogens in women decline dramatically at menopause,
whereas production of the main androgen, testosterone, in older men
wanes gradually and only slightly. Estrogens and testosterone stimulate
osteoblast activity and synthesis of bone matrix
 Rickets and osteomalacia are two forms of the same disease that result from
inadequate calcification of the extracellular bone matrix, usually caused by a
vitamin D deficiency.
 TOPICS FOR ILLUSTRATION

DRAW A NEAT LABELLED DIAGRAM OF THE GIVEN TOPICS ON PLAIN A4 SIZE PAPER – FOLLOW
RUBRICS
COMPLETED DIAGRAMS TO BE SUBMITTED FOR CORRECTION ON
30.09.2024 – sections 22/66 & 33/77 (Mon/Wed)
08.10.2024 – sections 44/88 (Tue/Thurs)

Parts of a long bone
 Date

Draw Margin for
very image

PARTS OF A LONG BONE

Your Name
 REFERENCES

Tortora, Gerard J. And Bryan H Derrickson. Principles of Anatomy and Physiology.
John Wiley & Sons, 2020

Standring, Susan. Gray’s Anatomy E-Book. Elsevier Health Sciences, 2015.
Parker, Steve. The Concise Human Body Book. 2019.
Feng X. (2009). Chemical and Biochemical Basis of Cell-Bone Matrix Interaction in
Health and Disease. Current chemical biology, 3(2), 189–196.
https://doi.org/10.2174/187231309788166398